高水温隧道温度场演变规律及注浆堵水隔热效果分析

doi:10.3724/1000-6915.jrme.2025.0377

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摘要为研究高水温隧道围岩热传导与热水–岩石对流换热2种传热机制共存情况下的温度场演变规律，通过推导热–流耦合围岩温度场的有限差分解，构建高温富水围岩与洞内空气耦合计算的三维数值模型，进行参数研究并分析注浆堵水隔热对温度的控制效果，通过研制与应用高水温隧道温度场模型试验系统对有限差分解和数值模拟结果进行验证。研究结果表明：（1）围岩渗透系数高于5×10－7 m/s引起的热水对流换热效应将使围岩长期保持在原始高温状态，随着渗透系数的降低，围岩温度随之降低，渗透系数降至1×10－9 m/s后，围岩降温幅度显著减弱。（2）注浆堵水隔热措施可有效削弱热水与围岩之间的对流换热效应，降低围岩与空气温度，但注浆圈的渗透系数与厚度对温度控制存在效应阈值，对于渗透系数为1×10－6 m/s的围岩，注浆区渗透系数低于围岩渗透系数的100倍，注浆区厚度3 m时的降温效果更加显著。（3）模型试验表明，高水温隧道通风初期围岩降温显著，后期趋于稳定，壁面温度变化趋势与有限差分解吻合良好，数值模拟与试验结果的壁面平均温度及出口空气温度相对误差分别小于15%和5%。建议在高水温隧道中采取结合注浆堵水与强化通风的综合措施，研究成果对类似高水温隧道的降温设计具有一定的理论参考与借鉴作用。

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	陈树杰1
	2
	朱正国1
	3
	谷广燕1
	安辰亮4
	马凯蒙1
	樊浩博1

关键词 ：隧道工程, 高水温, 有限差分解, 三维数值模型, 模型试验, 注浆堵水隔热

Abstract：To investigate the thermal evolution of surrounding rock in high-water-temperature tunnels where both heat conduction and convective heat transfer between geothermal water and rock coexist, this study derives a finite difference solution for the coupled thermal-hydraulic temperature field and develops a three-dimensional numerical model that integrates the high-temperature water-saturated rock mass with tunnel air. A parametric study is conducted to analyze the effectiveness of grouting for water sealing and thermal insulation. Additionally, a physical model test system for high-temperature tunnels is developed to validate the finite difference solution and numerical results. The findings indicate that: (1) when rock permeability exceeds 5×10?? m/s, convective heat transfer from thermal water maintains the rock at its initial high temperature; as permeability decreases, rock temperature declines, but further reduction below 1×10?? m/s yields diminishing cooling returns. (2) Grouting significantly reduces convective heat transfer between water and rock, thereby lowering the temperatures of both rock and air. For rock with a permeability of 1×10?? m/s, a grout zone with permeability two orders of magnitude lower and a thickness of 3 m achieves more pronounced cooling. (3) Model tests demonstrate that initial ventilation leads to rapid rock cooling, which stabilizes over time; wall temperature trends align with the finite difference solution, and the relative errors in wall and outlet air temperatures between simulation and experiment are within 15% and 5%, respectively. Combined grouting and enhanced ventilation are recommended for thermal control in high-temperature tunnels. The results provide theoretical guidance for the cooling design of similar geothermal tunnels.

Key words： tunnelling engineering high-water-temperature finite difference solution three-dimensional numerical model physical model test grouting-based thermal insulation

引用本文:

陈树杰1，2，朱正国1，3，谷广燕1，安辰亮4，马凯蒙1，樊浩博1. 高水温隧道温度场演变规律及注浆堵水隔热效果分析[J]. 岩石力学与工程学报, 2025, 44(12): 3349-3366.
CHEN Shujie1, 2, ZHU Zhengguo1, 3, GU Guangyan1, AN Chenliang4, MA Kaimeng1, FAN Haobo1. Evolutionary law of temperature field in thermal water-bearing tunnels and analysis of thermal insulation effect of grouting water-sealing. , 2025, 44(12): 3349-3366.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0377 或 https://rockmech.whrsm.ac.cn/CN/Y2025/V44/I12/3349

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